Display device and manufacturing method of the same

ABSTRACT

A display device includes a sequentially stacked body formed of a gate signal line, an insulation film, a semiconductor layer and a conductor layer on a substrate. The conductive layer forms a drain electrode and a source electrode of a thin film transistor which are arranged with a channel region of the semiconductor layer therebetween, and one of the drain and source electrode is formed in an approximately U shape having an open-ended one end side and a connecting portion on another end side so that the one electrode surrounds a distal end portion of another electrode as viewed in a plan view, and a projecting portion is formed on a side of the connecting portion opposite to the another electrode.

CROSS REFERENCE TO RELATED APPLICATION

This application is a divisional application of U.S. application Ser.No. 12/017,384, filed Jan. 22, 2008, now U.S. Pat. No. 7,829,395, thecontents of which are incorporated herein by reference.

The present application claims priority from Japanese applicationJP2007-12114 filed on Jan. 23, 2007, the content of which is herebyincorporated by reference into this application.

BACKGROUND OF THE INVENTION

1. Field of the Invention

The present invention relates to a display device and a manufacturingmethod of the display device, and more particularly to a display devicewhich includes thin film transistors and a manufacturing method of thedisplay device.

2. Description of the Related Art

This type of display device is configured such that a plurality ofpixels is arranged on a display part in a matrix array, each pixel rowformed of these pixels is sequentially selected by turning on the thinfilm transistors provided to the respective pixels in response toscanning signals supplied to the thin film transistors via the gatesignal line, and video signals are supplied to the respective pixels ofthe pixel row via a drain signal line which is connected tocorresponding pixels of another pixel row in common at timing of suchselection.

Further, as the thin film transistor, there has been known a so-calledbottom-gate-type transistor which arranges a gate electrode below asemiconductor layer. In manufacturing such a thin film transistor, amethod which is referred to as a resist reflow method may be used.

That is, a drain electrode and a source electrode are formed bypatterning a conductor layer formed on the semiconductor layer and,thereafter, a photoresist film formed on upper surfaces of theseelectrodes is made to remain, and the photoresist film is made to reflowto form a photoresist film (a modified photoresist film) whichconstitutes a mask for selectively etching the semiconductor layer.

By using such a method, in forming the mask for selectively etching thesemiconductor layer, the number of use of photolithography technique canbe omitted by one time and hence, the number of manufacturing steps canbe decreased.

The detail of the method is disclosed in patent document 1(JP-A-2002-83765), for example.

SUMMARY OF THE INVENTION

However, it is confirmed that the thin film transistor which is formedin this manner has following drawbacks. For example, in forming oneelectrode out of these electrodes into a U-shaped pattern, at aconnecting portion of two respective rod-shaped conductor layersarranged in parallel to each other, a recessed portion is formed to theinside from the outside and, in a worst case, the recessed portionprogresses thus separating the electrodes from each other at a portionof the connecting portion.

Upon seeking for causes of such a drawback, inventors of the presentinvention have found the property of the photoresist film that when thephotoresist film formed on the upper surfaces of the electrodes is madeto reflow, on an outer end portion (a distal end portion) of theconnecting portion of the electrode, the photoresist film does notreflow to sufficiently cover the outer end portion sufficiently andhence, a mask is not formed on such a portion.

It is an object of the present invention to provide a manufacturingmethod of a display device which can reliably form electrodes in a thinfilm transistor.

It is another object of the present invention to provide a displaydevice which can reliably form electrodes in a thin film transistor.

To briefly explain the summary of typical inventions among theinventions described in this application, they are as follows.

(1) method for manufacturing a display device according to the presentinvention includes, for example, the steps of: preparing a substratehaving a sequentially stacked body formed of a gate signal line, aninsulation film, a semiconductor layer and a conductor layer, forexample; forming a drain electrode and a source electrode of a thin filmtransistor at least in a region where the thin film transistor is formedin a pattern in which one of the drain electrode and the sourceelectrode is formed in an approximately U shape having an open-ended oneend side and a connecting portion on another end side such that oneelectrode surrounds a distal end portion of another electrode as viewedin a plan view and a projecting portion is formed on a side of theconnecting portion opposite to another electrode, wherein the respectiveelectrodes are formed by selectively etching the conductor layer using aphotoresist film as a mask; and etching the semiconductor layer using adeformed photoresist film which is formed by directly reflowing thephotoresist film as a mask.

(2) A display device according to the present invention is configured,for example, such that a gate signal line, an insulation film, asemiconductor layer and a conductor layer are sequentially stacked on asubstrate, for example, the conductor layer forms at least a drainelectrode and a source electrode of a thin film transistor which arearranged with a channel region of the semiconductor layer sandwichedtherebetween, the channel region overlaps the gate signal line, thedrain electrode and the source electrode are formed in a pattern inwhich one of the drain electrode and the source electrode is formed inan approximately U shape having an open-ended one end side and aconnecting portion on another end side such that one electrode surroundsa distal end portion of another electrode as viewed in a plan view and aprojecting portion is formed on a side of the connecting portionopposite to another electrode, and the semiconductor layer is formed ina pattern in which the semiconductor layer forms a protruding portionwhich extends outwardly including a portion where at least theprojecting portion is formed on the conductor layer as viewed in a planview.

(3) The display device according to the present invention is also, forexample, on a premise of the constitution (2), characterized in that theprojecting portion has a distal end thereof formed in a semicircularshape.

(4) The display device according to the present invention is also, forexample, on a premise of the constitution (2), characterized in that theprojecting portion has a distal end thereof formed in a rectangularshape.

(5) The display device according to the present invention is also, forexample, on a premise of the constitution (2), characterized in that oneelectrode is constituted of the drain electrode which is electricallyconnected to the drain signal line formed of the conductor layer via aconnecting portion, and the projecting portion is formed to functionalso as the connecting portion.

(6) A method for manufacturing a display device according to the presentinvention includes, for example, the steps of: preparing a substratehaving a sequentially stacked body formed of a gate signal line, aninsulation film, a semiconductor layer and a conductor layer, forexample; forming a drain electrode and a source electrode of a thin filmtransistor at least in a region where the thin film transistor is formedin a pattern in which one of the drain electrode and the sourceelectrode is formed in an approximately U shape having an open-ended oneend side and a connecting portion on another end side such that oneelectrode surrounds a distal end portion of another electrode as viewedin a plan view and the connecting portion of one electrode has a widthlarger than widths of other portions of one electrode, wherein therespective electrodes are formed by selectively etching the conductorlayer using a photoresist film as a mask; and etching the semiconductorlayer using a deformed photoresist film which is formed by directlyreflowing the photoresist film as a mask.

(7) A display device according to the present invention is configuredsuch that a gate signal line, an insulation film, a semiconductor layerand a conductor layer are sequentially stacked on a substrate, forexample, the conductor layer forms at least a drain electrode and asource electrode of a thin film transistor which are arranged with achannel region of the semiconductor layer sandwiched therebetween, thechannel region overlaps the gate signal line, the drain electrode andthe source electrode are formed in a pattern in which one of the drainelectrode and the source electrode is formed in an approximately U shapehaving an open-ended one end side and a connecting portion on anotherend side such that one electrode surrounds a distal end portion ofanother electrode as viewed in a plan view and the connecting portion ofone electrode has a large-width portion having a width larger thanwidths of other portions of one electrode, and the semiconductor layeris formed in a pattern in which the semiconductor layer forms aprotruding portion which extends outwardly including a portion whichincludes at least the large-width portion on the conductor layer asviewed in a plan view.

(8) The display device according to the present invention is also, forexample, on a premise of the constitution (7), characterized in that theconnecting portion of one electrode has a side portion thereof on a sideopposite to another electrode formed in a U shape and includes alarge-width portion covering the center of the connecting portion.

(9) The display device according to the present invention is also, forexample, on a premise of the constitution (7), characterized in that theconnecting portion of one electrode has a side portion thereof onanother-electrode side formed in a U shape and a side portion thereof ona side opposite to another electrode is formed in a U shape having arectangular shape.

Here, the present invention is not limited to the above-mentionedconstitutions and various modifications are conceivable withoutdeparting from the technical concept of the present invention.

The display device having such a constitution can reliably formelectrodes on the thin film transistor.

BRIEF DESCRIPTION OF THE DRAWINGS

FIG. 1 is a constitutional view of a display device according to oneembodiment of the present invention and also is a plan view showing apart of a thin film transistor;

FIG. 2 is an equivalent circuit diagram showing pixels of the displaydevice according to the embodiment of the present invention;

FIG. 3A to FIG. 3C are constitutional views of the pixel of the displaydevice according to the embodiment of the present invention;

FIG. 4A to FIG. 4F are views showing steps of a method for manufacturingthe display device according to the embodiment of the present invention;

FIG. 5 is a cross-sectional view of the display device in one step ofthe method for manufacturing the display device according to the presentinvention;

FIG. 6 is a constitutional view of a display device according to anotherembodiment of the present invention;

FIG. 7 is a constitutional view of a display device according to anotherembodiment of the present invention;

FIG. 8 is a constitutional view of a display device according to anotherembodiment of the present invention;

FIG. 9 is a constitutional view of a display device according to anotherembodiment of the present invention; and

FIG. 10 is an explanatory view of a drawback which arises when thepresent invention is not applied to a display device.

DESCRIPTION OF THE PREFERRED EMBODIMENTS

Hereinafter, an embodiment of a display device according to the presentinvention is explained in conjunction with drawings.

In FIG. 2, a liquid crystal display device is exemplified as a displaydevice according to the present invention, for example. FIG. 2 shows oneexample of an equivalent circuit of a pixel in a liquid crystal displaypart of the to liquid crystal display device according to oneembodiment. Further, FIG. 2 is a view showing a circuit which is formedon a liquid-crystal-side surface of one substrate SUB out of respectivesubstrates which are arranged to face each other in an opposed mannerwith liquid crystal sandwiched therebetween. The circuit includes 6pixels (=2×3 pixels), for example, which are arranged is close to eachother.

In FIG. 2, each pixel has a region thereof defined from regions of otherneighboring pixels by a pair of neighboring drain signal lines DL whichextends in the y direction in the drawing and a pair of neighboring gatesignal lines GL which extends in the x direction in the drawing.

Further, at one corner of the pixel, a thin film transistor TFT havingthe MIS structure is formed. The thin film transistor TFT has a gateelectrode thereof connected to a gate signal line GL arranged close tothe gate electrode and a drain electrode thereof connected to a drainsignal line DL which is arranged close to the drain electrode.

Further, in the region of each pixel, a pair of electrodes consisting ofa pixel electrode PX and a counter electrode CT is formed. The pixelelectrode PX is connected to a source electrode of the thin filmtransistor TFT, and the counter electrode CT is connected to a commonsignal line CL which extends in the x direction in the drawing.

In such a circuit constitution, a reference voltage (a voltage whichbecomes the reference with respect to a video signal) is applied to thecounter electrode CT of each pixel via the common signal line CL and agate voltage is sequentially applied to the gate signal lines GL from anupper side of the drawing, for example, so as to select the pixel row.By supplying a video signal to the respective drain signal lines DL attiming of the selection of the pixel row, a voltage of the video signalis applied to the pixel electrodes PX of the respective pixels of thepixel row via the thin film transistors TFT which are turned on with thegate voltage. Further, a so-called lateral electric field havingintensity corresponding to the voltage of the video signal is generatedbetween the pixel electrode PX and the counter electrode CT, and liquidcrystal molecules are driven in response to the intensity of the lateralelectric field.

In such a circuit, the gate signal lines GL, the drain signal lines DLand the thin film transistors TFT exhibit the substantially samegeometrical arrangements. However, for example, the counter electrode CTis formed in a planner shape in most of the region (80% or more, forexample) of the pixel, and the pixel electrode PX is constituted of aplurality of strip-shaped electrodes which overlaps the counterelectrode CT by way of an insulation film.

Accordingly, a capacitive element which uses the insulation film as adielectric film is formed between the pixel electrode PX and the counterelectrode CT together with the liquid crystal. When a video signal isapplied to the pixel electrode PX, the applied video signal is stored inthe capacitive element for a relatively long time.

FIG. 3A to FIG. 3C are views showing the constitution of the pixelformed on a liquid-crystal-side surface of the substrate SUB formed of atransparent substrate, for example. The pixel shown in FIG. 3A to FIG.3C indicates one pixel.

In FIGS. 3A to 3C, FIG. 3A is a plan view of the pixel, FIG. 3B is across-sectional view taken along a line b-b in FIG. 3A, and FIG. 3C is across-sectional view taken along a line c-c in FIG. 3A.

First of all, on the liquid-crystal-side surface (front surface) of thesubstrate SUB, the gate signal line GL and the common signal line CL areformed in parallel to each other with a relatively large distancetherebetween.

In a region defined between the gate signal line GL and the commonsignal line CL, the counter electrode CT made of a transparentconductive material such as ITO (Indium-Tin-Oxide), for example, isformed. The counter electrode CT is formed to overlap the common signalline CL at a common-signal-line-CL-side peripheral portion thereof sothat the counter electrode CT is electrically connected with the commonsignal line CL.

Further, the insulation film GI is formed on the surface of thesubstrate SUB in a state that the insulation film GI also covers thegate signal line GL, the common signal line CL and the counter electrodeCT. The insulation film GI functions as a gate insulation film of thethin film transistor TFT in a region where the thin film transistor TFTdescribed later is formed. A film thickness and the like of theinsulation film GI are set in view of such a function.

A semiconductor layer AS made of amorphous silicon, for example, isformed on an upper surface of the insulation film GI at a position wherethe semiconductor layer AS overlaps a portion of the gate signal lineGL. This semiconductor layer AS constitutes the semiconductor layer ofthe above-mentioned thin film transistor TFT.

Here, although it will become apparent by the explanation made later,the semiconductor layer AS is formed not only in the region where thethin film transistor TFT is formed but also below the drain signal lineDL, below a connecting portion JC which electrically connects the drainsignal line DL and the drain electrode DT of the thin film transistorTFT, and below a portion of the source electrode ST of the thin filmtransistor TFT which extends beyond a region where the thin filmtransistor TFT is formed respectively. Such a semiconductor layer AS isformed in the above-mentioned pattern by forming the thin filmtransistor TFT using a so-called registry flow method, for example. Inthis case, the formation of a stepped portion in the drain signal lineDL, for example, can be decreased and hence, it is possible to acquirean advantageous effect that a so-called broken step defect can beobviated. In the explanation made hereinafter, out of theabove-mentioned semiconductor layer AS, the semiconductor layer which isformed in the region other than the region where the thin filmtransistor TFT is formed may be also indicated by symbol AS'.

The drain signal line DL is formed in an extending manner in the ydirection in the drawing, and includes an extending portion whichextends toward the thin film transistor TFT side at a portion thereof.The extending portion (connecting portion JC) is connected to the drainelectrode DT of the thin film transistor TFT formed on the semiconductorlayer AS. Here, the connecting portion JC is formed on the gate signalline GL in an overlapping manner.

Further, the source electrode ST which is simultaneously formed with theformation of the drain signal line DL and the drain electrode DT facesthe drain electrode DT on the semiconductor layer AS in an opposedmanner and, at the same time, the source electrode ST has an extendingportion which slightly extends toward the pixel region side from thesemiconductor layer AS. This extending portion is configured such thatthe extending portion reaches a pad portion PD which is connected withthe pixel electrode PX explained later.

In forming the semiconductor layer AS on the insulation film GI, thesemiconductor layer AS is formed with a surface thereof doped withimpurity of high concentration, for example. After forming the drainelectrode DT and the source electrode ST by patterning, an impuritylayer of high concentration which is formed in a region other thanregions where the drain electrode DT and the source electrode ST areformed is etched using the drain electrode DT and the source electrodeST as masks. Due to such an operation, the impurity layer of highconcentration remains between the semiconductor layer AS and the drainelectrode DT as well as between the semiconductor layer AS and thesource electrode ST, and the impurity layer forms an ohmic contactlayer.

Due to such steps, as the thin film transistor TFT, the MIS-structuretransistor having the so-called inverse staggered structure which usesthe gate signal line GL as the gate electrode is formed.

The MIS-structure transistor is driven such that the drain electrode DTand the source electrode ST are changed over in response to applying ofa bias. In the explanation made in this specification, for the sake ofconvenience, the electrode on a side connected to the drain signal lineDL is referred to as the drain electrode DT, and the electrode on a sideconnected to the pixel electrode PX is referred to as the sourceelectrode ST.

A protective film PAS is formed on a surface of the substrate SUB in astate that the protective film PAS also covers the thin film transistorsTFT. The protective film PAS is provided for preventing the directcontact of the thin film transistor TFT with liquid crystal. Further,the protective film PAS is interposed as a layer between the counterelectrode CT and the pixel electrode PX described later and alsofunctions as a dielectric film of the capacitive element formed betweenthe counter electrode CT and the pixel electrode PX along with theabove-mentioned insulation film GI.

The pixel electrode PX is formed on an upper surface of the protectivefilm PAS. The pixel electrode PX is made of a transparent conductivematerial such as ITO (Indium-Tin-Oxide), for example, and is formed onthe counter electrode CT in an overlapping manner with a wideoverlapping area.

Here, a large number of slits are formed in the pixel electrode PX inparallel in the direction intersecting the longitudinal direction of thepixel electrode PX thus being configured to have a group of electrodesconsisting of a large number of strip-shaped electrodes which have bothends thereof connected to each other.

Further, on the surface of the substrate SUB, an orientation film (notshown in the drawing) is formed in a state that the orientation filmalso covers the pixel electrode PX. This orientation film is providedfor setting the initial orientation direction of molecules of liquidcrystal which is in direct contact with the orientation film.

With respect to the respective electrodes of the pixel electrode PX, asshown in FIG. 3A, the region of the pixel is divided in two verticallyin the drawing, for example, wherein the respective electrodes in oneregion are formed to extend in the direction of +45° with respect to therunning direction of the gate signal line GL, and the respectiveelectrodes in another region are formed to extend in the direction of−45° with respect to the running direction of the gate signal line GL,for example. That is, the pixel electrode PX adopts a so-calledmulti-domain method. This method can eliminate a drawback that coloringoccurs depending on the viewing direction when the direction of theslits formed in the pixel electrode PX (the direction of the group ofelectrodes forming the pixel electrode PX) in one pixel is the singledirection. Accordingly, it is not always necessary for the pixelelectrode PX to adopt such a constitution.

In the above-mentioned embodiment, the semiconductor layer of the thinfilm transistor TFT is made of amorphous silicon. However, thesemiconductor layer of the thin film transistor TFT may be made ofpoly-silicon.

FIG. 1 is a plan view of the thin film transistor TFT shown in FIG. 3Ato FIG. 3C (a portion indicated by a dotted frame Q in the drawing) inan enlarged manner.

The semiconductor layer AS is formed on an upper surface of theinsulation film GI (not shown in the drawing) formed to cover the gatesignal line GL.

The semiconductor layer AS is formed by selective etching which uses aphoto resist film (a deformed photo resist film) having thesubstantially same shape as the conductor layer formed on an uppersurface of the semiconductor layer AS by patterning as a mask. Thepattern schematically has the substantially same shape as the conductorlayer. The pattern of the semiconductor layer AS is explained later infurther detail.

The conductor layer is, first of all, constituted of the drain electrodeDT and the source electrode ST of the thin film transistor TFT formed onthe semiconductor layer AS which is arranged on the gate signal line GLin an overlapping manner.

The drain electrode DT has an approximately U-shape as viewed in a planview. That is, the drain electrode DT is formed in a pattern in whichtwo rod-shaped respective conductor layers are arranged in parallel withthe longitudinal direction thereof aligned with the y direction in thedrawing, and a connecting portion CB is formed by connecting therespective conductor layers to each other using a conductor layer in alower portion of the drawing (one end of the drain electrode DT havingan opening portion at an upper end portion thereof in the drawing).

The drain electrode DT is formed in a pattern in which theabove-mentioned two rod-shaped respective conductor layers and theconductor layer which constitutes the connecting portion CB are formedsuch that the respective widths of these conductor layers are madesubstantially uniform and, at the same time, a projecting portion PJhaving a semicircular shape is formed on an approximately center portionof the connecting portion CB on a side opposite to the channel regionCH.

Due to such a constitution, a width of the approximately center portionof the connecting portion CB of the drain electrode DT is set largerthan widths of portions of the drain electrode DT other than the centerportion of the connecting portion CB.

The drain electrode DT formed in such a pattern is, as will becomeapparent later, configured to obviate an unfavorable phenomenon that, informing the drain electrode DT, the connecting portion CB is formed in apattern in which a side of the connecting portion CB opposite to thechannel region CH is recessed excessively and, in a worst case, theconnecting portion CB is separated or divided.

Here, the drain electrode DT is formed along with the formation of thedrain signal line DL by performing selective etching of the conductorlayer, and is configured to include the connecting portion JC forestablishing the electrical connection with the drain signal line DL.

Further, the source electrode ST is formed simultaneously with theformation of the drain electrode DT, and the source electrode ST isformed in a linear pattern in which the source electrode ST is insertedinto the U-shaped drain electrode DT from the opening portion andextends toward the connecting-portion-CB side, and is arranged in theextending manner in the y direction in the drawing.

Due to such a constitution, the drain electrode DT is formed in apattern in which the drain electrode DT surrounds a distal end portionof the source electrode ST as viewed in a plan view, and a U-shapedchannel region CH in which the drain electrode DT and the sourceelectrode ST face each other is formed on a surface of a semiconductorlayer AS. Due to such a constitution, it is possible to increase achannel width in the channel region CH.

Here, the source electrode ST extends toward the pixel region side in anupper portion of the drawing relative to the gate signal line GL whilegetting over the gate signal line GL, and is connected to the padportion PD for establishing the connection of the source electrode STwith the pixel electrode PX not shown in the drawing. The pad portion PDis also formed by selective etching of the conductor layer and is formedtogether with the source electrode ST.

Further, the semiconductor layer AS is configured to have a protrudingportion. This protruding portion slightly extends outwardly not onlyfrom a lower region of the conductor layer which constitutes the drainsignal line DL, the connecting portion JC, the drain electrode DT, thesource electrode ST and the pad portion PD respectively (a region whichoverlaps the conductor layer), and the channel region CH defined betweenthe drain electrode DT and the source electrode ST respectively but alsofrom a profile which is defined by these regions along the substantiallywhole circumference of the profile.

Here, the expression that the protruding portion of the semiconductorlayer AS extends outwardly along the “substantially” whole circumferenceof the profile implies that at portions of the whole circumference ofthe profile, for example, at electrode ends TE of the drain electrode DTon the opening portion of the drain electrode DT (a portion on a sideopposite to the connecting portion CB), the semiconductor layer AS doesnot protrude to the outside of the profile in some cases. When suchprotruding portions such as the electrode ends TE are present on theconductor layer, in reflowing the photoresist film, there may be a casein which the photoresist film does not extend and flow to the outside ofthe electrode ends TE to cover the electrode ends TE.

However, also in this case, since the projecting portion PJ is formed inthe connecting portion CB of the drain electrode DT, it is possible toensure the projecting portion PJ and the protrusion of the semiconductorlayer AS to the outside of the connecting portion CB.

By forming the projecting portion PJ on the drain electrode DT, thephotoresist film before reflowing is increased by an amountcorresponding to a portion thereof formed above the projecting portionPJ. Accordingly, in reflowing the photoresist film, the photoresist filmeasily flows while extending toward the outside of the distal end of theprojecting portion PJ so that the projecting portion PJ is sufficientlycovered with the deformed photoresist film.

FIG. 4A to FIG. 4F are step views of a manufacturing method of thedisplay device according to one embodiment of the present inventionshowing a portion of the thin film transistor TFT. The respective stepviews shown in FIG. 4A to FIG. 4F indicate a cross section taken along aline VI-VI in FIG. 1. Hereinafter, the manufacturing method is explainedin order of steps in conjunction with FIG. 4A to FIG. 4F.

Firstly, as shown in FIG. 4A, the substrate SUB which forms the gatesignal lines GL and the insulation film GI on a main surface(liquid-crystal-side surface) thereon is prepared. Here, the insulationfilm GI also covers the gate signal lines GL.

On a whole area of an upper surface of the insulation film GI formed onthe substrate SUB, the semiconductor layer AS and the conductor layerCDT are sequentially stacked using a CVD method, for example.

Here, the semiconductor layer AS is made of amorphous Si, for example,and a surface of the semiconductor layer AS is doped with n-typeimpurity of high concentration thus forming a high concentrationimpurity layer CNL. This high-concentration impurity layer CNL functionsas an ohmic contact layer of the thin film transistor TFT.

Next, as shown in FIG. 4B, a photoresist film is applied to a whole areaof a surface of the conductor layer CDT, and the photoresist film isformed by patterning by selectively removing the photoresist film usinga well-known photolithography technique.

Here, a pattern of the remaining photoresist film PTR is substantiallyequal to a pattern of the conductor layer CDT which is expected toremain by selective etching.

Next, as shown in FIG. 4C, the conductor layer CDT and thehigh-concentration impurity layer CNL are sequentially selectivelyetched using the remaining photoresist film PTR as a mask. Here, forexample, the conductor layer CDT is etched by so-called wet etching andthe high-concentration impurity layer CNL is etched by dry etching.

The remaining conductor layer CDT acquired by selective etching formsthe drain electrode DT and the source electrode ST of the thin filmtransistor TFT, the drain signal line DL connected to the drainelectrode DT (including the connecting portion JC with the drainelectrode DT), and the pad portion PD of the source electrode ST whichis connected with the pixel electrode.

Here, even at a stage in which selective etching of the conductor layerCDT and the high-concentration impurity layer CNL is finished, theprocessing advances to the next step without removing the photoresistfilm PTR.

Next, as shown in FIG. 4D, a deformed photoresist film PTR′ is formed byreflowing the photoresist film PTR. The deformed photoresist film PTR′formed by reflowing is formed such that, for example, the photoresistfilm PTR is exposed to vapor of an organic solvent solution for 1 to 3minutes thus gradually impregnating the organic solvent solution intothe photoresist film PTR whereby the photoresist film PTR is dissolvedby the organic solvent solution.

Due to this reflowing, the photoresist film PTR formed above thepatterned conductor layer CDT flows and extends, as viewed in a planview, to the outside of the conductor layer CDT. In other words, thephotoresist film PTR flows and protrudes from a profile of the conductorlayer CDT.

In this case, when another conductor layer CDT is arranged close to theconductor layer CDT, the photoresist film PTR which flows from theconductor layer CDT and the photoresist film PTR which flows fromanother conductor layer CDT are merged with each other and hence, anarrow region defined between the conductor layer CDT and anotherconductor layer CDT is filled with the photoresist film PTR (PTR′). Thatis, a portion corresponding to the channel region CH defined between thedrain electrode DT and the source electrode ST is filled with thedeformed photoresist film PTR′.

Further, in reflowing the photoresist film PTR, there may be a case thatthe photoresist film does not sufficiently cover the electrode ends TEof an opening portion (a portion on a side opposite to theconnecting-portion-CB side of the drain electrode DT out of theconductor layer CDT. This is because that, as mentioned previously, inreflowing the photoresist film PTR, the photoresist film PTR has aproperty which makes the flowing of the photoresist film PTR to theoutside of the electrode end TE difficult.

Then, at a distal end PE of the projecting portion PJ formed on theconnecting portion CB of the drain electrode DT, as mentionedpreviously, the photoresist film PTR which is formed above theprojecting portion PJ reflows such that the photoresist film PTR coversthe projecting portion PJ. FIG. 5 which is a cross-sectional view takenalong a line V-V in FIG. 1 is a view showing a state in which thedeformed photoresist film PTR′ formed by reflowing sufficiently coversthe connecting portion CB of the drain electrode DT together with theprojecting portion PJ.

In this case, even when the conductor layer CDT is made of, for example,aluminum (Al), titanium (Ti) or molybdenum (Mo) and the semiconductorlayer AS is selectively etched by dry etching, the conductor layer CDTis sufficiently covered with the deformed photoresist film PTR′ andhence, this embodiment can also acquire an advantageous effect that theoccurrence of hillock from the conductor layer CDT can be obviated.

Next, as shown in FIG. 4E, using the deformed photoresist film PTR′formed by reflowing as a mask, a portion of the semiconductor layer ASexposed from the mask is selectively etched by dry etching, for example.Due to such selective etching, the semiconductor layer AS is formed bypatterning shown in FIG. 1.

Then, as shown in FIG. 4F, by removing the deformed photoresist filmPTR′, the formation of the thin film transistor TFT is finished. Afterthe formation of the thin film transistor TFT, the protective film PASis formed on the surface of the substrate SUB in a state that theprotective film PAS covers the thin film transistor TFT, and the pixelelectrode PX is formed on an upper surface of the protective film PAS.

Here, in manufacturing the display device through these steps, when thedrain electrode DT of the thin film transistor TFT is formed in apattern with no projecting portion PJ, as shown in FIG. 10 whichcorresponds to FIG. 1, there may be a case that a recessed portion SCPmay is formed in a portion of an outer side of the connecting portion CBof the drain electrode DT together with the semiconductor layer ASformed below the drain electrode DT. This is because that etching isperformed in a state that the deformed photoresist film PTR′ does notcover the drain electrode DT sufficiently at such a portion.

In the above-mentioned embodiment, although the projecting portion PJformed on the drain electrode DT of the thin film transistor TFT isformed in a semicircular shape, the shape of the projecting portion PJis not limited to such a shape. For example, as shown in FIG. 6 which isdepicted corresponding to FIG. 1, the projecting portion PJ formed onthe drain electrode DT may have a rectangular shape. That is, it issufficient that by forming the projecting portion PJ, a width of theapproximately center portion of the connecting portion CB of the drainelectrode DT is set larger than widths of portions of the drainelectrode DT other than the connecting portion CB.

Based on such a definition of the projecting portion PJ, as shown inFIG. 7, the drain electrode DT may be formed in a pattern in which thedrain electrode DT has a width w at an opening-portion side and thewidth of the drain electrode DT is gradually increased toward the centerportion of the connecting portion CB and the width assumes a maximumwidth W (>w) at the center portion of the connecting portion CB.

Further, as shown in FIG. 8, the drain electrode DT may be formed in a Ushape having an arcuate portion at the connecting portion CB on asource-electrode-ST side and an approximately U-shape having arectangular portion at the connecting portion CB on a side opposite tothe source-electrode-ST side thus forming a pattern in which the widthof the drain electrode DT assumes a width w on the opening-portion sideand a width W (>w) at the center portion of the connecting portion CB.

Further, FIG. 9 shows a case in which in forming the projecting portionPJ on the connecting portion CB of the drain electrode DT of the thinfilm transistor TFT, the projecting portion PJ is also configured tofunction as the connecting portion JC which connects the drain electrodeDT to the drain signal line DL.

To provide such a constitution, in FIG. 9, the U-shaped drain electrodeDT is, for example, configured such that two respective rod-shapedconductor layers on an opening portion side of the drain electrode DTare arranged in parallel to each other with the longitudinal directionthereof aligned with the x direction in the drawing, and the connectingportion CB is positioned on the drain-signal-line-DL side.

Further, to provide such a constitution, the source electrode ST whichis arranged in the extending manner in the x direction in the drawing isbent on a side at which the source electrode ST is connected to thepixel electrode PX (not shown in the drawing), and is connected to thepad portion PD on the pixel region at an upper portion of the drawingwith respect to the gate signal line GL.

The thin film transistor TFT having such a constitution can acquireadvantageous effects similar to the advantageous effects acquired by theprojecting portion PJ shown in FIG. 1, for example, by the provision ofthe connecting portion JC which establishes the electrical connectionbetween the drain electrode DT and the drain signal line DL. Further,the drain electrode DL is formed in a pattern in which the drainelectrode DL has a width w at the opening-portion side thereof and awidth W (>w) at the center portion of the connecting portion CB.

In the respective embodiments explained heretofore, it is needless tosay that the source electrode ST is formed in a U-shape in place offorming the drain electrode DT in a U-shape.

In the liquid crystal display device of the above-mentioned embodiment,the liquid crystal (liquid crystal molecules) is configured to be drivenby an electric field referred to as a so-called lateral electric fieldwith respect to the substrate (SUB). However, the present invention isnot limited to the liquid crystal display device which adopts thelateral electric field for driving the liquid crystal but also isapplicable to a liquid crystal display device which adopts an electricfield referred to as a so-called vertical electric field, for example,for driving the liquid crystal.

In the above-mentioned embodiments, the display device of the presentinvention has been explained by taking the liquid crystal display deviceas an example. However, the present invention is also applicable toother display device such as an organic EL display device, for example.This is because the organic EL display device is also configured byproviding a thin film transistor for every pixel, for example, and hastasks to be solved which are substantially equal to the above-mentionedtasks to be solved.

The above-mentioned respective embodiments may be used in a single formor in combination. This is because these embodiments can acquire theadvantageous effects of the respective embodiments individually orsynergistically.

1. A display device being configured such that a gate signal line, aninsulation film, a semiconductor layer and a conductor layer aresequentially stacked on a substrate, the conductor layer forms at leasta drain electrode and a source electrode of a thin film transistor and adrain signal line which are arranged with a channel region of thesemiconductor layer sandwiched therebetween, the channel region overlapsthe gate signal line, the drain electrode and the source electrode areformed in a pattern in which the drain electrode is formed in anapproximately U shape having an open-ended one end side of the U shapeand a connecting portion on another end side of the U shape such thatthe drain electrode surrounds a distal end portion of the sourceelectrode as viewed in plan view and a projecting portion is formed on aside of the connecting portion opposite to the source electrode, and thesemiconductor layer and the conductor layer overlap, and thesemiconductor layer forms a protruding portion which extends outwardlybeyond the conductor layer including at the projecting portion as viewedin plan view.
 2. A display device according to claim 1, wherein theprojecting portion has a distal end thereof formed in a semicircularshape.
 3. A display device according to claim 1, wherein the projectingportion has a distal end thereof formed in a rectangular shape.
 4. Adisplay device according to claim 1, wherein the drain electrode iselectrically connected to the drain signal line via the connectingportion, and the projecting portion is formed to function also as theconnecting portion.
 5. A display device according to claim 1, whereinthe protruding portion of the semiconductor layer extends outwardlybeyond the conductor layer at the projecting portion, at the drainelectrode including the connecting portion, at the source electrode, andat the drain signal line, as viewed in plan view.